Potassium Fixation by Amorphous Aluminosilica Gels

Abstract--Noncrystalline aluminosilicates termed allophane and imogolite are common constituents of spodosols, soils derived from volcanic ash, and many inceptisols. The surface charge characteristics of their synthetic analogues may be used to better understand their ion retention properties. In this study, we determined the point of zero salt effect (PZSE) by potentiometric titration of allophanes with A1/Si ratios of 1.12, 1.52, and 2.04 and of imogolite with an A1/Si ratio of 2.02. We also used microelectrophoresis to determine the point of zero charge (PZC) at the particle shear plane for the same materials in C1 solutions of Li, Na, Cs, and tetramethyl ammonium. The PZSE decreased with decreasing A1/Si ratio for the allophanes, but the imogolite PZSE was much lower than that of the allophane with 2.04 A1/Si. The PZC was always higher than the PZSE of the same material, especially for imogolite. The results are best explained if cations reside within the hollow tubes ofimogolite. This conclusion is supported by a fluorescence study that showed that only quenchers smaller than the inner diameter of the imogolite tube could fully quench Ce-imogolite.

Section: Nature Of Titratable Sites In Imogolite and Allophanementioning

confidence: 99%

Adsorption of Cations on Imogolite and their Effect on Surface Charge Characteristics

Harsh

Traina

Boyle

et al. 1992

“…The structural models for amorphous aluminosilicares proposed by Cloos et al (1969) and van Reeuwijk and de Villiers (1970) provide a useful basis for understanding the surface charge characteristics of these materials. These models consider amorphous aluminosilicates to be composed of two intimately associated phases: an aluminosilicate phase resulting from the isomorphous substitution of tetrahedrally co-ordinated A1 for Si in a silica structure with a negative charge which is neutralized, at least partially, by a positively charged phase composed of hydroxyaluminium species.…”

Section: Synthetic Aluminosilicatesmentioning

confidence: 99%

“…(1964) confirmed the presence of tetrahedral A1 by X-ray fluorescence measurements. CEC variations with aluminosilicate composition have been explained by the models of Cloos et al (1969) and van Reeuwijk and de Villiers (1970), which consider amorphous aluminosilicates to consist of an aluminosilicate phase with permanent negative charge arising from isomo! 'phous substitution of A1 for Si, and a hydroxyaluminium phase with pH-dependent positive charge.…”

Section: Introductionmentioning

confidence: 99%

Surface Charge Characteristics of Amorphous Aluminosilicates

Perrott

1977

Abstract--The surface charge characteristics of a range of synthetic amorphous aluminosilicates, hydrous alumina, hydrous silica and two allophanic soil clays were determined by the retention of Na ~ and C1 as counter-ions from 0.1 M NaC1 solution. In the pH range investigated (3-9), only negative charges could be detected in the hydrous silica and the most siliceous aluminosilicate [A1/(A1 + Si) = 0.29], and only positive charges were detected in the hydrous alumina; whereas both positive and negative charges were detected in the more aluminous aluminosilicates and the soil allophanes. In all cases, the surface charges were pH-dependent and in the aluminosilicate series negative charge decreased and positive charge increased with A1/(A1 + Si). Consequently, the point of zero charge increased with AI/(A1 + Si).The charge characteristics of the amorphous aluminosilicates could be explained by current models of their structure. Negative charge can be attributed to isomorphous substitution of A1 for Si in the silicate structure and to the dissociation of silanol groups in structural and adsorbed silicate. Positive charge is attributed to protonation of hydroxy-aluminum species occupying cation exchange sites.

“…These gels were included for investigation because of the importance which has previously been attached (Cloos et al, 1969;van Reeuwijk and de Villiers, 1970) to their study as a means towards elucidating the nature and properties of allophane.…”

Section: Selective Dissolution By Other Reagentsmentioning

confidence: 99%

Properties and Quantitative Estimation of Poorly Crystalline Components in Sesquioxidic Soil Clays

Fey

Roux

1977

Abstract--Sesquioxidic soil clays from Oxisols in South Africa, Australia and Brazil, and two clays from Andosols in Japan and New Zealand, were investigated by selective dissolution techniques. Acid ammonium oxalate (pH 3) was found to be superior to currently popular alkaline reagents for extracting amorphous aluminosilicates and alumina from these clays. Boiling 0.5 N NaOH dissolved large amounts of finely-divided kaolinite and halloysite, while hot 5~ Na2CO 3 reaction was too slow (partial dissolution of synthetic amorphous aluminosilicates with one extraction) and insufficiently selective (gibbsite and kaolin of poor crystallinity dissolve to a variable extent). On the other hand, synthetic gels (molar SiO2/A120 ~ ranging from 0.91 to 2.55) dissolved completely after 2 hr shaking in the dark with 0.2 M acid ammonium oxalate (0.2 ml/mg). Specificity of oxalate for natural allophane was indicated by removal of similar quantities of silica and alumina using different clay:solution .ratios. Oxalate extraction data indicated that allophane is absent in Oxisol clays. Allophane was determined quantitatively in volcanic-ash soil clays by allocating hydroxyl water content to oxalate-soluble silica plus alumina on the basis of an ignition weight los~chemical composition function for synthetic amorphous aluminosilicates. Parameters of chemical reactivity and distribution of electric charges following various chemical pretreatments of allophane were found to correspond closely to those predicted on the basis of synthetic gel behaviour. Results for Oxisol clays suggested that the role of amorphous (oxalate-soluble) alumina in governing physicochemical properties is generally less than that of the poorly-crystalline, Al-substituted iron oxide component which is removed by deferration with citrate~tithionite-bicarbonate reagent.